Replication of plasmids from Staphylococcus aureus in Escherichia coli

Plasmid-Mediated Biodegradation of Chlorpyrifos and Analysis of Its Metabolic By-Products

Organophosphate pesticide persistence is an emerging menace to the environment and despite this fact, its use has been enhanced due to its high efficiency. Bioremediation using microorganisms would be the only means by which these hazardous compounds could be wiped out without disturbing the environmental harmony. The current work studied the molecular mechanism of degradation of Chlorpyrifos (CP) by a bacterial consortium C5 comprising of three soil isolates Staphylococcus warneri (CPI 2), Pseudomonas putida (CPI 9) and Stenotrophomonas maltophilia (CPI 15), which unveiled that the property is plasmid borne. All the isolates were found to possess a 4 kb plasmid which could be cured only by using sodium azide. The Escherichia coli JM109 cells when transformed individually with the plasmid of the isolates showed CP degradation in mineral salts medium (MSM) that contained CP as the sole carbon source. The degradative enzyme organophosphorus hydrolase (~ 60 KDa) of the isolates was extracted and purified to 31.85, 26 and 37.74 fold, respectively. The possible metabolic by-products of CP degradation by the consortium C5, were also analysed. The LC-Q-Tof MS analysis revealed the presence of the major metabolite 3, 5, 6 -trichloropyridine (TCP) with the formation of chlorpyrifos oxon as the intermediate. The isolates also showed trichloropyridine degradation (> 80%) individually in MSM-TCP medium proving its efficiency to remediate both CP and TCP.

Dynamic Genome Editing Using In Vivo Synthesized Donor ssDNA in Escherichia coli

As a key element of genome editing, donor DNA introduces the desired exogenous sequence while working with other crucial machinery such as CRISPR-Cas or recombinases. However, current methods for the delivery of donor DNA into cells are both inefficient and complicated. Here, we developed a new methodology that utilizes rolling circle replication and Cas9 mediated (RC-Cas-mediated) in vivo single strand DNA (ssDNA) synthesis. A single-gene rolling circle DNA replication system from Gram-negative bacteria was engineered to produce circular ssDNA from a Gram-positive parent plasmid at a designed sequence in Escherichia coli. Furthermore, it was demonstrated that the desired linear ssDNA fragment could be cut out using CRISPR-associated protein 9 (CRISPR-Cas9) nuclease and combined with lambda Red recombinase as donor for precise genome engineering. Various donor ssDNA fragments from hundreds to thousands of nucleotides in length were synthesized in E. coli cells, allowing successive genome editing in growing cells. We hope that this RC-Cas-mediated in vivo ssDNA on-site synthesis system will be widely adopted as a useful new tool for dynamic genome editing.

Mobilizable Rolling-Circle Replicating Plasmids from Gram-Positive Bacteria: A Low-Cost Conjugative Transfer

Conjugation is a key mechanism for horizontal gene transfer in bacteria. Some plasmids are not self-transmissible but can be mobilized by functions encoded in trans provided by other auxiliary conjugative elements. Although the transfer efficiency of mobilizable plasmids is usually lower than that of conjugative elements, mobilizable plasmidsare more frequently found in nature. In this sense, replication and mobilization can be considered as important mechanisms influencing plasmid promiscuity. Here we review the present available information on two families of small mobilizable plasmids from Gram-positive bacteria that replicate via the rolling-circle mechanism. One of these families, represented by the streptococcal plasmid pMV158, is an interesting model since it contains a specific mobilization module (MOB_V) that is widely distributed among mobilizable plasmids. We discuss a mechanism in which the promiscuity of the pMV158 replicon is based on the presence of two origins of lagging strand synthesis. The current strategies to assess plasmid transfer efficiency as well as to inhibit conjugative plasmid transfer are presented. Some applications of these plasmids as biotechnological tools are also reviewed.

Identification of the Minimal Replicon of Lactococcus lactis subsp. lactis UC317 Plasmid pCI305

Replication functions of the stable, cryptic 8.7-kilobase (kb) plasmid pCI305 from multi-plasmid-containing Lactococcus lactis subsp. lactis UC317 were studied. Analysis of this replicon was facilitated by the construction of replication probe vectors that consisted of the pBR322 replication region, a pUC18-derived multiple cloning site, and either the cat gene of pC194 (pCI341; 3.1 kb) or the erm gene of pAMbeta1 (pCI3330; 4.0 kb). Plasmid pCI305 was introduced into plasmid-free L. lactis subsp. lactis MG1363Sm, a streptomycin-resistant derivative of MG1363, by a transformation procedure with the 75-kb lactose-proteinase plasmid pCI301 of UC317 as a marker plasmid. A combination of transposon Tn5 mutagenesis and subcloning in pCI341 and pCI3330 with individual Tn5 insertions around the replication region facilitated the identification of a 1.6-kb minimal replicon on pCI305. This region was separable into two domains: (i) a 1.3-kb region (repB) encoding a trans-acting function (in vitro transcription-translation studies suggested the involvement of a 48-kilodalton protein); and (ii) a 0.3-kb region (repA) sufficient to direct replication when provided with repB in trans and thus probably containing the origin of replication. Lactococcus-Escherichia coli shuttle vectors based on the pCI305 replication region were constructed.

New yeast recombineering tools for bacteria

Recombineering with Saccharomyces cerevisiae is a powerful methodology that can be used to clone multiple unmarked pieces of DNA to generate complex constructs with high efficiency. Here, we introduce two new tools that utilize the native recombination enzymes of S. cerevisiae to facilitate the manipulation of DNA. First, yeast recombineering was used to make directed nested deletions in a bacteria-yeast shuttle plasmid using only one or two single stranded oligomers, thus obviating the need for a PCR step. Second, we have generated several new shuttle vectors for yeast recombineering capable of replication in a wide variety of bacterial genera. As a demonstration of utility, some of the approaches and vectors generated in this study were used to make a pigP deletion mutation in the opportunistic pathogen Serratia marcescens.

A novel rolling-circle-replicating plasmid from Pseudomonas putida P8: molecular characterization and use as vector

In Pseudomonas putida P8, three cryptic circular plasmids were detected, i.e. pPP8-1 (2.5 kbp), pPP8-2 (42 kbp) and pPP8-3 (approximately 100 kbp). Cloning and complete sequencing of pPP8-1 revealed a 2534 bp element harbouring four open reading frames (ORFs A, B, C and D). No function could be attributed to the latter three ORFs, whereas the predicted ORF A gene product is homologous to replication proteins known from small multicopy plasmids of Gram-positive bacteria and single-stranded (ss) phages, genetic elements replicating via a rolling circle (RC) mechanism involving characteristic ssDNA intermediates. Consistently, a double-strand origin of replication, highly conserved in rolling-circle-replicating (RCR) elements, was identified in pPP8-1, along with a putative single-strand origin. Beyond this, ss replication intermediates were confirmed by Southern analysis and mungbean-nuclease digestion. This being the first element of this type known in pseudomonads, a kanamycin-resistance gene was ligated into pPP8-1 and the resulting vector was successfully used for the transformation of both Escherichia coli and P. putida.

UvrD-dependent replication of rolling-circle plasmids in Escherichia coli

The Escherichia coli UvrD helicase (or helicase II) is known for its involvement in DNA repair. We report that UvrD is required for DNA replication of several different rolling-circle plasmids in E. coli, whereas its homologue, the Rep helicase, is not. Lack of UvrD helicase does not impair the first step of plasmid replication, nicking of the double-stranded origin by the plasmid initiator protein. However, replication proceeds no further without UvrD. Indeed, the nicked plasmid molecules accumulate to a high level in uvrD mutants. We conclude that UvrD is the replicative helicase of various rolling-circle plasmids. This is the first description of a direct implication of UvrD in DNA replication in vivo.

Identification of the Chi site of Haemophilus influenzae as several sequences related to the Escherichia coli Chi site

The Escherichia coli Chi site 5'-GCTGGTGG-3' modulates the activity of the powerful dsDNA exonuclease and helicase RecBCD. Genome sequence analyses revealed that Chi is frequent on the chromosome and oriented with respect to replication on the E. coli genome. Chi is also present much more frequently than predicted statistically for a random 8-mer sequence. Although it is assumed that Chi is ubiquitous, there is virtually no proof that its features are conserved in other microorganisms. We therefore identified and analysed the Chi sequence of an organism for which the full genome sequence was available, Haemophilus influenzae. The biological test we used is based on our finding that rolling circle plasmids provide a specific substrate for RecBCD analogues in different microorganisms. Unexpectedly, several related sequences, corresponding to 5'-GNTGGTGG-3' and 5'-G(G/C)TGGAGG-3', showed Chi activity. As in E. coli, the H. influenzae Chi sites are frequent on the genome, which is in keeping with the need for frequent Chi sites for dsDNA break repair of chromosomal DNA. Although statistically over-represented, this feature is less marked than that of the E. coli Chi site. In contrast to E. coli, the H. influenzae Chi motifs are only slightly oriented with respect to the replication strand. Thus, although Chi appears to have a highly conserved biological role in attenuating exonuclease activity, its sequence characteristics and statistical representation on the genome may differ according to the particular features of the host.

Neomycin- and spectinomycin-resistance replacement vectors for Bacillus subtilis

A plasmid is described for Bacillus subtilis that facilitates replacement of the widely used neomycin resistance gene (neo) with a spectinomycin resistance (spcE) gene. A second plasmid is described that facilitates replacement of spcS, associated with mini-Tn10 mutagenesis in B. subtilis, with neo. These plasmids can also function as integrative vectors for B. subtilis. They expand the scope of strain construction and gene analysis in B. subtilis.

A fourth class of theta-replicating plasmids: the pAM beta 1 family from gram-positive bacteria

Plasmid pAM beta 1 from Enterococcus faecalis uses a unidirectional theta mode of replication. We show here that this replication (i) is dependent on a plasmid-encoded replication protein (Rep) but not on a DNA structure typical for origins of most Rep-dependent plasmids and (ii) is initiated by DNA polymerase I (PolI). pAM beta 1 minimal replicon shares no homology with highly conserved ColE1-type replicons, which use PolI for initiation but do not encode a Rep, or with ColE2 and ColE3 replicons, which require PolI for replication and encode a Rep. We propose that pAM beta 1 and a number of other naturally occurring and closely related plasmids from a distinct plasmid class.

Rolling circle-replicating plasmids from gram-positive and gram-negative bacteria: a wall falls

Rolling circle-replicating plasmids constitute a group of small, promiscuous multicopy replicons spread among eubacteria. Until recently, rolling circle replication seemed to be limited to small plasmids from Gram-positive hosts and to single-stranded bacteriophages from Gram-negative bacteria. However, characterization of two small plasmids from Gram-negative hosts has shown that this replication mechanism is general among eubacteria. This review focuses on a family of highly related promiscuous plasmids that replicate by the rolling circle mechanism, and that have been isolated from various Gram-positive bacteria and from the Gram-negative bacterium Helicobacter. They all share homologies at the leading-strand origins and at the initiator of replication proteins. The plasmids of this family have directly repeated sequences at their plus origin of replication, which is located 5' from the start point of the mRNA for the initiation of replication protein. Replication is controlled by an antisense RNA and by a transcriptional repressor protein. The features and regulatory circuits of replication of this plasmid family seem to be unique among rolling circle-replicating plasmids. Members of this family replicate autonomously in Gram-positive and -negative hosts.

Transformation of the gram-positive bacterium Clavibacter xyli subsp. cynodontis by electroporation with plasmids from the IncP incompatibility group

We report the transformation of a gram-positive bacterium, Clavibacter xyli subsp. cynodontis, with several plasmids in the IncP incompatibility group from gram-negative bacteria. Our results suggest that IncP plasmids may be transferable to other gram-positive organisms. After optimizing electroporation parameters, we obtained a maximum of 2 x 10(5) transformants per microgram of DNA. The availability of a transformation system for this bacteria will facilitate its use in indirectly expressing beneficial traits in plants.

The Escherichia coli terB sequence affects maintenance of a plasmid with the M13 phage replication origin

Replication initiated at the bacteriophage M13 origin can be affected by interaction of a properly oriented termination signal terB and the Tus protein. The effect can be alleviated by overproduction of the M13 replication gene protein II.

Plus-origin mapping of single-stranded DNA plasmid pE194 and nick site homologies with other plasmids

Staphylococcus aureus plasmid pE194 manifests a natural thermosensitivity for replication and can be established in several species, both gram positive and gram negative, thus making it attractive for use as a delivery vector. Like most characterized plasmids of gram-positive bacteria, pE194 generates single-stranded DNA. The direction of pE194 replication is clockwise, as determined by the strandedness of free single-stranded DNA. Significant homology exists between a 50-base-pair sequence in the origin of pE194 and sequences present in plasmids pMV158 (Streptococcus agalactiae), pADB201 (Mycoplasma mycoides), and pSH71 (Lactococcus lactis). We used an initiation-termination reaction, in which pE194 initiates replication at its own origin and is induced to terminate at the related pMV158 sequence, to demonstrate that pE194 replicates by a rolling-circle mechanism; the initiation nick site was localized to an 8-base-pair sequence.

The family of highly interrelated single-stranded deoxyribonucleic acid plasmids

Many plasmids from gram-positive bacteria replicate via a single-stranded deoxyribonucleic acid (ssDNA) intermediate, most probably by a rolling-circle mechanism (these plasmids are referred to in this paper as ssDNA plasmids). Their plus and minus origins are physically separated, and replicative initiations are not simultaneous; it is this feature that allows visualization of ssDNA replication intermediates. The insertion of foreign DNA into an ssDNA plasmid may provoke a high frequency of deletions, changes of replicative products to high-molecular-weight forms, segregational loss, and decreased plasmid copy numbers. When an ssDNA plasmid is inserted into the chromosome, both deletions and amplifications may be induced. Both the mode of replication and the copy control mechanism affect the fate of inserted foreign material, usually selecting for its loss. Thus, after having tasted various morsels of DNA, the resulting plasmid stays trim. The features of the ssDNA plasmids seem to be beneficial for their viability and propagation, but not for their use as cloning vectors. However, plasmids replicating via ssDNA intermediates are being exploited to yield insights into the mechanisms of recombination and amplification.

Replication origins of single-stranded-DNA plasmid pUB110

The two replication origins of plasmid pUB110 have been characterized. The site of initiation of DNA replication at the plus origin was mapped to within an 8-base-pair sequence. DNA synthesis initiated at the origin was made to terminate precociously in an inserted sequence of 18 base pairs that is homologous to a sequence in the origin. This suggests that pUB110 replicates as a rolling circle. The minus origin of plasmid pUB110 has been characterized, and the minimal sequence required for function has been determined. As with other minus origins, activity is orientation specific with respect to the direction of replication. Its activity is sensitive to rifampin in vivo, suggesting that RNA polymerase catalyzes single-strand to double-strand conversion. Unlike all other plasmids of gram-positive bacteria thus far described, the pUB110 minus origin is functional in more than one host.

Transformation of Corynebacterium diphtheriae, Corynebacterium ulcerans, Corynebacterium glutamicum, and Escherichia coli with the C. diphtheriae plasmid pNG2

The transfection and transformation of members of two species of pathogenic corynebacteria, Corynebacterium diphtheriae and Corynebacterium ulcerans, is described. Protoplasts were produced by treatment with lysozyme following growth in glycine, and a medium was defined on which a significant fraction of the osmotically sensitive cells were regenerated. Transfections were carried out with DNA from corynephage 782, a member of the beta family of converting phages, and transformations were performed with DNA of plasmid pNG2, a 9500-kDa plasmid that was isolated from an erythromycin-resistant strain of C. diphtheriae and carries the resistance gene. Strains of Corynebacterium glutamicum and Escherichia coli were also successfully transformed with pNG2 DNA. Transfection frequencies were in the range of 3-8 X 10(3) plaque-forming units/micrograms of phage DNA, and transformation frequencies were in the range of 0.2-150 colony-forming units/micrograms of plasmid DNA. Plasmid pNG2 replicated and was stably maintained in all transformants both in the presence or absence of erythromycin. Thus, it displayed the ability to replicate in strains of both Gram-positive and Gram-negative bacteria without the intervention of genetic engineering. pNG2 DNA isolated from any of the transformed strains was able to transform all parental strains. The host range of pNG2 suggests its possible utility in or as a shuttle vector for the study and manipulation of genes from corynebacterial strains of animal origin.

Antimicrobial resistance of Staphylococcus aureus: genetic basis

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Replication of the streptococcal plasmid pMV158 and derivatives in cell-free extracts of Escherichia coli

pMV158 is a 5.4 kb broad host range multicopy plasmid specifying tetracycline resistance. This plasmid and two of its derivatives, pLS1 and pLS5, are stably maintained and express their genetic information in gram-positive and gram-negative hosts. The in vitro replication of plasmid pMV158 and its derivatives was studied in extracts prepared from plasmid-free Escherichia coli cells and the replicative characteristics of the streptococcal plasmids were compared to those of the E. coli replicons, ColE1 and the mini-R1 derivative pKN182. The optimal replicative activity of the E. coli extracts was found at a cellular phase of growth that corresponded to 2 g wet weight of cells per litre. Maximal synthesis of streptococcal plasmid DNA occurred after 90 min of incubation and at a temperature of 30 degrees C. The optimal concentration of template DNA was 40 micrograms/ml. Higher plasmid DNA concentrations resulted in a decrease in the incorporation of dTMP, indicating that competition of specific replication factor(s) for functional plasmid origins may occur. In vitro replication of plasmid pMV158 and its derivatives required the host RNA polymerase and de novo protein synthesis. The final products of the streptococcal plasmid DNAs replicated in the E. coli in vitro system were monomeric supercoiled DNA forms that had completed at least one round of replication, although a set of putative replicative intermediates could also be found. The results suggest that a specific plasmid-encoded factor is needed for the replication of the streptococcal plasmids.

Single-stranded plasmid DNA in Bacillus subtilis and Staphylococcus aureus

Plasmid pC194 was found to exist in a double-stranded and a single-stranded DNA form in Bacillus subtilis and Staphylococcus aureus. This single-stranded DNA was found as a circular molecule of the same size as the parental monomer and corresponded to only one of the two DNA strands. It represented one-third of plasmid copies. Single- and double-stranded DNA copies in similar proportions to the above were detected for five other S. aureus plasmids (pC221, pC223, pE194, pT127, and pT181) and one B. subtilis plasmid (pHV416). S. aureus plasmid pUB110 and Bacillus cereus plasmid pBC16 were, in contrast, predominantly double-stranded.

Construction of plasmid cloning vectors for lactic streptococci which also replicate in Bacillus subtilis and Escherichia coli

The cryptic Streptococcus cremoris Wg2 plasmid pWV01 (1.5 megadaltons) was genetically marked with the chloramphenicol resistance (Cmr) gene from pC194. The recombinant plasmid (pGK1, 2.4 megadaltons) replicated and expressed Cmr in Bacillus subtilis. From this plasmid an insertion-inactivation vector was constructed by inserting the erythromycin resistance (Emr) gene from pE194 cop-6. This plasmid (pGK12, 2.9 megadaltons) contained a unique BclI site in the Emr gene and unique ClaI and HpaII sites outside both resistance genes. It was stably maintained in B. subtilis at a copy number of approximately 5. pGK12 also transformed Escherichia coli competent cells to Cmr and Emr. The copy number in E. coli was about 60. Moreover, pGK12 transformed protoplasts of Streptococcus lactis. In this host both resistance genes are expressed. pGK12 is stably maintained in S. lactis at a copy number of 3.

Introduction of plasmid pC194 into Bacillus thuringiensis by protoplast transformation and plasmid transfer

The Staphylococcus aureus plasmid pC194 which codes for resistance to chloramphenicol was introduced into six Bacillus thuringiensis strains representing five varieties by protoplast transformation. Six other varieties could not be transformed. pC194 could be identified in transformed strains as autonomous plasmid. The transformed clones contained in addition a new extrachromosomal element of somewhat lower electrophoretic mobility hybridizing with pC194, and pC194 in multimeric forms. pC194 was also transferred from one B. thuringiensis variety to another and from Bacillus thuringiensis to Bacillus subtilis and vice versa by a conjugation-like process, requiring close cell-to-cell contact.

Isolation and complementation of temperature-sensitive replication mutants of Staphylococcus aureus plasmid pC194

Temperature-sensitive replication (Tsr) mutants have been isolated from the Staphylococcus aureus plasmid pC194. For three of the four mutant plasmids tested (pSAO801, pSAO802, and pSAO804) the segregation kinetics suggested a complete block of plasmid replication at 43 degrees C. The replication defects of three mutant plasmids: pSAO802, pSAO803, and pSAO804 could be complemented by recombinant plasmids carrying a segment from either the wild type or the other mutant, pSAO801. There was no complementation when the segment carried by the recombinant plasmid was derived from one of the three complementable mutants. These data were taken as evidence for the involvement of a diffusible, plasmid-encoded product, RepH, in pC194 replication. The complementation of the fourth Tsr mutant, pSAO801, could not be tested due to an abnormal susceptibility of this mutant to the incompatibility expressed by recombinants carrying segments derived from pC194 or its mutants. A single mutation was found to be responsible for both pSAO801 instability and its altered incompatibility properties but the nature of the defect has not yet been elucidated.

Chloramphenicol acetyltransferase: enzymology and molecular biology

Naturally occurring chloramphenicol resistance in bacteria is normally due to the presence of the antibiotic inactivating enzyme chloramphenicol acetyltransferase (CAT) which catalyzes the acetyl-S-CoA-dependent acetylation of chloramphenicol at the 3-hydroxyl group. The product 3-acetoxy chloramphenicol does not bind to bacterial ribosomes and is not an inhibitor of peptidyltransferase. The synthesis of CAT is constitutive in E. coli and other Gram-negative bacteria which harbor plasmids bearing the structural gene for the enzyme, whereas Gram-positive bacteria such as staphylococci and streptococci synthesize CAT only in the presence of chloramphenicol and related compounds, especially those with the same stereochemistry of the parent compound and which lack antibiotic activity and a site of acetylation (3-deoxychloramphenicol). Studies of the primary structures of CAT variants suggest a marked degree of heterogeneity but conservation of amino acid sequence at and near the putative active site. All CAT variants are tetramers composed in each case of identical polypeptide subunits consisting of approximately 220 amino acids. The catalytic mechanism does not appear to involve an acyl-enzyme intermediate although one or more cysteine residues are protected from thiol reeagents by substrates. A highly reactive histidine residue has been implicated in the catalytic mechanism.

Plasmids from Staphylococcus aureus replicate in yeast Saccharomyces cerevisiae

It is known that some plasmids, such as RP4, can replicate in many Gram-negative bacteria. Certain small Staphylococcus aureus plasmids have an even broader host range, being able to replicate in not only phylogenetically distant Gram-positive bacteria such as Bacillus subtilis or Streptococcus pneumoniae, but also in the Gram-negative bacterium Escherichia coli. Here we have examined whether these plasmids can also replicate in a lower eukaryote, the yeast Saccharomyces cerevisiae. For this purpose we constructed hybrids between a S. aureus plasmid pC194 and an E. coli plasmid YIp5, which carries a ura-3 gene easy to select for in yeast but cannot replicate in this host. We found that the hybrids transformed yeast with high efficiency (as did hybrids between YIp5 and three other S. aureus plasmids); were maintained extrachromosomally in yeast; and were not modified during residence in yeast. We conclude from this evidence that S. aureus plasmids can replicate in yeast, which raises the questions of whether the replication signals used by prokaryotes and eukaryotes are similar, and how far up the phylogenetic tree the organisms still able to be hosts to S. aureus plasmids may be.

Coding sequence for the pT181 repC product: a plasmid-coded protein uniquely required for replication

pT181 is a 4.4-kilobase plasmid from Staphylococcus aureus specifying tetracycline resistance and present in about 20 copies per cell. The existence of a diffusible pT181 product required for plasmid replication has been proposed on the basis of trans-complementable thermosensitive mutants defective in plasmid maintenance (phenotype Tsr). In this report, the Tsr mutants are shown to have primary replication defects, and the genetic complementation data are confirmed biochemically. All of five mutations are in a single cistron, the repC cistron; interruption of the plasmid DNA molecule at any of three neighboring restriction sites inactivates repC function. Analysis of the DNA sequence in this region reveals an open reading frame of 939 base pairs which encodes the repC product, a 313-amino acid protein. pT181 replication has been demonstrated in cell-free extracts to require specifically a pT181-coded protein of approximately the same size, and it is proposed that this protein is, indeed, the repC product. Preliminary evidence is discussed suggesting that the pT181 replication rate is controlled at the level of synthesis of the repC protein.

Nucleotide sequence and functional map of pC194, a plasmid that specifies inducible chloramphenicol resistance

The nucleotide sequence of pC194, a small plasmid from Staphylococcus aureus which is capable of replication in Bacillus subtilis, has been determined. The genetic determinant of chloramphenicol (CAM) resistance, which includes the chloramphenicol acetyl transferase (CAT) structural gene, the putative promoter and controlling element of this determinant, have been mapped functionally by subcloning a 1,035-nucleotide fragment which specifies the resistance phenotype using plasmid pBR322 as vector. Expression of CAM resistance is autogenously regulated since the 1,035-nucleotide fragment containing the CAT gene sequence and its promoter cloned into pBR322 expresses resistance inducibly in the Escherichia coli host. A presumed controlling element of CAT expression consists of a 37-nucleotide inverted complementary repeat sequence that is located between the -10 and ribosome-loading sequences of the CAT structural gene. Whereas the composite plasmid containing the minimal CAT determinant cloned in pBR322 could not replicate in B. subtilis, ability to replicate in B. subtilis was seen if the fragment cloned included an extension consisting of an additional 300 nucleotides beyond the 5' end of the single pC194 MspI site associated with replication. This 5' extension contained a 120-nucleotide inverted complementary repeat sequence similar to that found in pE194 TaqI fragment B which contains replication sequences of that plasmid. pC194 was found to contain four opening reading frames theoretically capable of coding for proteins with maximum molecular masses, as follows: A, 27,800 daltons; B, 26,200 daltons; C, 15,000 daltons; and D, 9,600 daltons. Interruption or deletion of either frame A or D does not entail loss of ability to replicate or to express CAM resistance, whereas frame B contains the CAT structural gene and frame C contains sequences associated with plasmid replication.

Staphylococcal plasmids that replicate and express erythromycin resistance in both Streptococcus pneumoniae and Escherichia coli

Plasmid pSA5700 from Staphylococcus aureus coding for erythromycin (EmR) and chloramphenicol (CmR) resistance was transformed into Streptococcus pneumoniae. High-copy-number and EmR constitutive mutants of this plasmid were isolated. Transformation frequencies in S. pneumoniae as high as 70% were obtained with a constitutive plasmid as donor DNA, into a recipient cell containing a resident, inducible, high-copy-number plasmid. With the aid of these high frequencies, the site of constitutive mutations could be mapped via a simple marker rescue technique that uses purified restriction endonuclease-generated fragments. One of the EmR constitutive mutants, pFB9, a plasmid originating from a Gram-positive host, was shown to replicate and express EmR and CmR in a Gram-negative organism, Escherichia coli. Four derivatives of pFB9 containing large (0.6-0.9 megadalton) insertion sequences that arose spontaneously in E. coli demonstrated unusual transforming activity, as well as enhanced EmR, in E. coli. The inserted elements mapped to the region in front of the EmR gene. Three of these inserted elements had the size and restriction patterns of insertion sequence IS1, IS2, and IS5. Plasmid pFB9 and derivatives are useful for isolation of new insertion sequences and for comparison of gene expression and illegitimate recombination between Gram-positive and Gram-negative species.